/****************************************************************************** * * $Id$ * * Copyright (C) 2006 Florian Pose, Ingenieurgemeinschaft IgH * * This file is part of the IgH EtherCAT Master. * * The IgH EtherCAT Master is free software; you can redistribute it * and/or modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 of the * License, or (at your option) any later version. * * The IgH EtherCAT Master is distributed in the hope that it will be * useful, but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with the IgH EtherCAT Master; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA * * The right to use EtherCAT Technology is granted and comes free of * charge under condition of compatibility of product made by * Licensee. People intending to distribute/sell products based on the * code, have to sign an agreement to guarantee that products using * software based on IgH EtherCAT master stay compatible with the actual * EtherCAT specification (which are released themselves as an open * standard) as the (only) precondition to have the right to use EtherCAT * Technology, IP and trade marks. * *****************************************************************************/ /** \file Ethernet-over-EtherCAT (EoE). */ /*****************************************************************************/ #include #include #include "../include/ecrt.h" #include "globals.h" #include "master.h" #include "slave.h" #include "mailbox.h" #include "ethernet.h" /** Defines the debug level of EoE processing 0 = No debug messages. 1 = Output actions. 2 = Output actions and frame data. */ #define EOE_DEBUG_LEVEL 0 /*****************************************************************************/ void ec_eoe_flush(ec_eoe_t *); // state functions void ec_eoe_state_rx_start(ec_eoe_t *); void ec_eoe_state_rx_check(ec_eoe_t *); void ec_eoe_state_rx_fetch(ec_eoe_t *); void ec_eoe_state_tx_start(ec_eoe_t *); void ec_eoe_state_tx_sent(ec_eoe_t *); // net_device functions int ec_eoedev_open(struct net_device *); int ec_eoedev_stop(struct net_device *); int ec_eoedev_tx(struct sk_buff *, struct net_device *); struct net_device_stats *ec_eoedev_stats(struct net_device *); /*****************************************************************************/ /** EoE constructor. Initializes the EoE handler, creates a net_device and registeres it. */ int ec_eoe_init(ec_eoe_t *eoe /**< EoE handler */) { ec_eoe_t **priv; int result, i; eoe->slave = NULL; ec_datagram_init(&eoe->datagram); eoe->state = ec_eoe_state_rx_start; eoe->opened = 0; eoe->rx_skb = NULL; eoe->rx_expected_fragment = 0; INIT_LIST_HEAD(&eoe->tx_queue); eoe->tx_frame = NULL; eoe->tx_queue_active = 0; eoe->tx_queued_frames = 0; eoe->tx_queue_lock = SPIN_LOCK_UNLOCKED; eoe->tx_frame_number = 0xFF; memset(&eoe->stats, 0, sizeof(struct net_device_stats)); if (!(eoe->dev = alloc_netdev(sizeof(ec_eoe_t *), "eoe%d", ether_setup))) { EC_ERR("Unable to allocate net_device for EoE handler!\n"); goto out_return; } // initialize net_device eoe->dev->open = ec_eoedev_open; eoe->dev->stop = ec_eoedev_stop; eoe->dev->hard_start_xmit = ec_eoedev_tx; eoe->dev->get_stats = ec_eoedev_stats; for (i = 0; i < ETH_ALEN; i++) eoe->dev->dev_addr[i] = i | (i << 4); // initialize private data priv = netdev_priv(eoe->dev); *priv = eoe; // Usually setting the MTU appropriately makes the upper layers // do the frame fragmenting. In some cases this doesn't work // so the MTU is left on the Ethernet standard value and fragmenting // is done "manually". #if 0 eoe->dev->mtu = slave->sii_rx_mailbox_size - ETH_HLEN - 10; #endif // connect the net_device to the kernel if ((result = register_netdev(eoe->dev))) { EC_ERR("Unable to register net_device: error %i\n", result); goto out_free; } // make the last address octet unique eoe->dev->dev_addr[ETH_ALEN - 1] = (uint8_t) eoe->dev->ifindex; return 0; out_free: free_netdev(eoe->dev); eoe->dev = NULL; out_return: return -1; } /*****************************************************************************/ /** EoE destructor. Unregisteres the net_device and frees allocated memory. */ void ec_eoe_clear(ec_eoe_t *eoe /**< EoE handler */) { if (eoe->dev) { unregister_netdev(eoe->dev); free_netdev(eoe->dev); } // empty transmit queue ec_eoe_flush(eoe); if (eoe->tx_frame) { dev_kfree_skb(eoe->tx_frame->skb); kfree(eoe->tx_frame); } if (eoe->rx_skb) dev_kfree_skb(eoe->rx_skb); ec_datagram_clear(&eoe->datagram); } /*****************************************************************************/ /** Empties the transmit queue. */ void ec_eoe_flush(ec_eoe_t *eoe /**< EoE handler */) { ec_eoe_frame_t *frame, *next; spin_lock_bh(&eoe->tx_queue_lock); list_for_each_entry_safe(frame, next, &eoe->tx_queue, queue) { list_del(&frame->queue); dev_kfree_skb(frame->skb); kfree(frame); } eoe->tx_queued_frames = 0; spin_unlock_bh(&eoe->tx_queue_lock); } /*****************************************************************************/ /** Sends a frame or the next fragment. */ int ec_eoe_send(ec_eoe_t *eoe /**< EoE handler */) { size_t remaining_size, current_size, complete_offset; unsigned int last_fragment; uint8_t *data; #if EOE_DEBUG_LEVEL > 1 unsigned int i; #endif remaining_size = eoe->tx_frame->skb->len - eoe->tx_offset; if (remaining_size <= eoe->slave->sii_tx_mailbox_size - 10) { current_size = remaining_size; last_fragment = 1; } else { current_size = ((eoe->slave->sii_tx_mailbox_size - 10) / 32) * 32; last_fragment = 0; } if (eoe->tx_fragment_number) { complete_offset = eoe->tx_offset / 32; } else { complete_offset = remaining_size / 32 + 1; } #if EOE_DEBUG_LEVEL > 0 EC_DBG("EoE TX sending %sfragment %i with %i octets (%i)." " %i frames queued.\n", last_fragment ? "last " : "", eoe->tx_fragment_number, current_size, complete_offset, eoe->tx_queued_frames); #endif #if EOE_DEBUG_LEVEL > 1 EC_DBG(""); for (i = 0; i < current_size; i++) { printk("%02X ", frame->skb->data[eoe->tx_offset + i]); if ((i + 1) % 16 == 0) { printk("\n"); EC_DBG(""); } } printk("\n"); #endif if (!(data = ec_slave_mbox_prepare_send(eoe->slave, &eoe->datagram, 0x02, current_size + 4))) return -1; EC_WRITE_U8 (data, 0x00); // eoe fragment req. EC_WRITE_U8 (data + 1, last_fragment); EC_WRITE_U16(data + 2, ((eoe->tx_fragment_number & 0x3F) | (complete_offset & 0x3F) << 6 | (eoe->tx_frame_number & 0x0F) << 12)); memcpy(data + 4, eoe->tx_frame->skb->data + eoe->tx_offset, current_size); ec_master_queue_datagram(eoe->slave->master, &eoe->datagram); eoe->tx_offset += current_size; eoe->tx_fragment_number++; return 0; } /*****************************************************************************/ /** Runs the EoE state machine. */ void ec_eoe_run(ec_eoe_t *eoe /**< EoE handler */) { if (!eoe->opened) return; // call state function eoe->state(eoe); } /*****************************************************************************/ /** Returns the state of the device. \return 1 if the device is "up", 0 if it is "down" */ unsigned int ec_eoe_active(const ec_eoe_t *eoe /**< EoE handler */) { return eoe->slave && eoe->opened; } /*****************************************************************************/ /** Prints EoE handler information. */ void ec_eoe_print(const ec_eoe_t *eoe /**< EoE handler */) { EC_INFO(" EoE handler %s\n", eoe->dev->name); EC_INFO(" State: %s\n", eoe->opened ? "opened" : "closed"); if (eoe->slave) EC_INFO(" Coupled to slave %i.\n", eoe->slave->ring_position); else EC_INFO(" Not coupled.\n"); } /****************************************************************************** * STATE PROCESSING FUNCTIONS *****************************************************************************/ /** State: RX_START. Starts a new receiving sequence by queueing a datagram that checks the slave's mailbox for a new EoE datagram. */ void ec_eoe_state_rx_start(ec_eoe_t *eoe /**< EoE handler */) { if (!eoe->slave->online || !eoe->slave->master->device->link_state) return; ec_slave_mbox_prepare_check(eoe->slave, &eoe->datagram); ec_master_queue_datagram(eoe->slave->master, &eoe->datagram); eoe->state = ec_eoe_state_rx_check; } /*****************************************************************************/ /** State: RX_CHECK. Processes the checking datagram sent in RX_START and issues a receive datagram, if new data is available. */ void ec_eoe_state_rx_check(ec_eoe_t *eoe /**< EoE handler */) { if (eoe->datagram.state != EC_CMD_RECEIVED) { eoe->stats.rx_errors++; eoe->state = ec_eoe_state_tx_start; return; } if (!ec_slave_mbox_check(&eoe->datagram)) { eoe->state = ec_eoe_state_tx_start; return; } ec_slave_mbox_prepare_fetch(eoe->slave, &eoe->datagram); ec_master_queue_datagram(eoe->slave->master, &eoe->datagram); eoe->state = ec_eoe_state_rx_fetch; } /*****************************************************************************/ /** State: RX_FETCH. Checks if the requested data of RX_CHECK was received and processes the EoE datagram. */ void ec_eoe_state_rx_fetch(ec_eoe_t *eoe /**< EoE handler */) { size_t rec_size, data_size; uint8_t *data, frame_type, last_fragment, time_appended; uint8_t frame_number, fragment_offset, fragment_number; off_t offset; if (eoe->datagram.state != EC_CMD_RECEIVED) { eoe->stats.rx_errors++; eoe->state = ec_eoe_state_tx_start; return; } if (!(data = ec_slave_mbox_fetch(eoe->slave, &eoe->datagram, 0x02, &rec_size))) { eoe->stats.rx_errors++; eoe->state = ec_eoe_state_tx_start; return; } frame_type = EC_READ_U16(data) & 0x000F; if (frame_type == 0x00) { // EoE Fragment Request last_fragment = (EC_READ_U16(data) >> 8) & 0x0001; time_appended = (EC_READ_U16(data) >> 9) & 0x0001; fragment_number = EC_READ_U16(data + 2) & 0x003F; fragment_offset = (EC_READ_U16(data + 2) >> 6) & 0x003F; frame_number = (EC_READ_U16(data + 2) >> 12) & 0x000F; #if EOE_DEBUG_LEVEL > 0 EC_DBG("EoE RX fragment %i, offset %i, frame %i%s%s," " %i octets\n", fragment_number, fragment_offset, frame_number, last_fragment ? ", last fragment" : "", time_appended ? ", + timestamp" : "", time_appended ? rec_size - 8 : rec_size - 4); #endif #if EOE_DEBUG_LEVEL > 1 EC_DBG(""); for (i = 0; i < rec_size - 4; i++) { printk("%02X ", data[i + 4]); if ((i + 1) % 16 == 0) { printk("\n"); EC_DBG(""); } } printk("\n"); #endif data_size = time_appended ? rec_size - 8 : rec_size - 4; if (!fragment_number) { if (eoe->rx_skb) { EC_WARN("EoE RX freeing old socket buffer...\n"); dev_kfree_skb(eoe->rx_skb); } // new socket buffer if (!(eoe->rx_skb = dev_alloc_skb(fragment_offset * 32))) { if (printk_ratelimit()) EC_WARN("EoE RX low on mem. frame dropped.\n"); eoe->stats.rx_dropped++; eoe->state = ec_eoe_state_tx_start; return; } eoe->rx_skb_offset = 0; eoe->rx_skb_size = fragment_offset * 32; eoe->rx_expected_fragment = 0; } else { if (!eoe->rx_skb) { eoe->stats.rx_dropped++; eoe->state = ec_eoe_state_tx_start; return; } offset = fragment_offset * 32; if (offset != eoe->rx_skb_offset || offset + data_size > eoe->rx_skb_size || fragment_number != eoe->rx_expected_fragment) { eoe->stats.rx_errors++; eoe->state = ec_eoe_state_tx_start; dev_kfree_skb(eoe->rx_skb); eoe->rx_skb = NULL; return; } } // copy fragment into socket buffer memcpy(skb_put(eoe->rx_skb, data_size), data + 4, data_size); eoe->rx_skb_offset += data_size; if (last_fragment) { // update statistics eoe->stats.rx_packets++; eoe->stats.rx_bytes += eoe->rx_skb->len; #if EOE_DEBUG_LEVEL > 0 EC_DBG("EoE RX frame completed with %u octets.\n", eoe->rx_skb->len); #endif // pass socket buffer to network stack eoe->rx_skb->dev = eoe->dev; eoe->rx_skb->protocol = eth_type_trans(eoe->rx_skb, eoe->dev); eoe->rx_skb->ip_summed = CHECKSUM_UNNECESSARY; if (netif_rx(eoe->rx_skb)) { EC_WARN("EoE RX netif_rx failed.\n"); } eoe->rx_skb = NULL; eoe->state = ec_eoe_state_tx_start; } else { eoe->rx_expected_fragment++; #if EOE_DEBUG_LEVEL > 0 EC_DBG("EoE RX expecting fragment %i\n", eoe->rx_expected_fragment); #endif eoe->state = ec_eoe_state_rx_start; } } else { #if EOE_DEBUG_LEVEL > 0 EC_DBG("other frame received.\n"); #endif eoe->stats.rx_dropped++; eoe->state = ec_eoe_state_tx_start; } } /*****************************************************************************/ /** State: TX START. Starts a new transmit sequence. If no data is available, a new receive sequence is started instead. */ void ec_eoe_state_tx_start(ec_eoe_t *eoe /**< EoE handler */) { #if EOE_DEBUG_LEVEL > 0 unsigned int wakeup; #endif if (!eoe->slave->online || !eoe->slave->master->device->link_state) return; spin_lock_bh(&eoe->tx_queue_lock); if (!eoe->tx_queued_frames || list_empty(&eoe->tx_queue)) { spin_unlock_bh(&eoe->tx_queue_lock); // no data available. // start a new receive immediately. ec_eoe_state_rx_start(eoe); return; } // take the first frame out of the queue eoe->tx_frame = list_entry(eoe->tx_queue.next, ec_eoe_frame_t, queue); list_del(&eoe->tx_frame->queue); if (!eoe->tx_queue_active && eoe->tx_queued_frames == EC_EOE_TX_QUEUE_SIZE / 2) { netif_wake_queue(eoe->dev); eoe->tx_queue_active = 1; #if EOE_DEBUG_LEVEL > 0 wakeup = 1; #endif } eoe->tx_queued_frames--; spin_unlock_bh(&eoe->tx_queue_lock); eoe->tx_frame_number++; eoe->tx_frame_number %= 16; eoe->tx_fragment_number = 0; eoe->tx_offset = 0; if (ec_eoe_send(eoe)) { dev_kfree_skb(eoe->tx_frame->skb); kfree(eoe->tx_frame); eoe->tx_frame = NULL; eoe->stats.tx_errors++; eoe->state = ec_eoe_state_rx_start; return; } #if EOE_DEBUG_LEVEL > 0 if (wakeup) EC_DBG("waking up TX queue...\n"); #endif eoe->state = ec_eoe_state_tx_sent; } /*****************************************************************************/ /** State: TX SENT. Checks is the previous transmit datagram succeded and sends the next fragment, if necessary. */ void ec_eoe_state_tx_sent(ec_eoe_t *eoe /**< EoE handler */) { if (eoe->datagram.state != EC_CMD_RECEIVED) { eoe->stats.tx_errors++; eoe->state = ec_eoe_state_rx_start; return; } if (eoe->datagram.working_counter != 1) { eoe->stats.tx_errors++; eoe->state = ec_eoe_state_rx_start; return; } // frame completely sent if (eoe->tx_offset >= eoe->tx_frame->skb->len) { eoe->stats.tx_packets++; eoe->stats.tx_bytes += eoe->tx_frame->skb->len; dev_kfree_skb(eoe->tx_frame->skb); kfree(eoe->tx_frame); eoe->tx_frame = NULL; eoe->state = ec_eoe_state_rx_start; } else { // send next fragment if (ec_eoe_send(eoe)) { dev_kfree_skb(eoe->tx_frame->skb); kfree(eoe->tx_frame); eoe->tx_frame = NULL; eoe->stats.tx_errors++; eoe->state = ec_eoe_state_rx_start; } } } /****************************************************************************** * NET_DEVICE functions *****************************************************************************/ /** Opens the virtual network device. */ int ec_eoedev_open(struct net_device *dev /**< EoE net_device */) { ec_eoe_t *eoe = *((ec_eoe_t **) netdev_priv(dev)); ec_eoe_flush(eoe); eoe->opened = 1; netif_start_queue(dev); eoe->tx_queue_active = 1; EC_INFO("%s opened.\n", dev->name); if (!eoe->slave) EC_WARN("device %s is not coupled to any EoE slave!\n", dev->name); else { eoe->slave->requested_state = EC_SLAVE_STATE_OP; eoe->slave->error_flag = 0; } return 0; } /*****************************************************************************/ /** Stops the virtual network device. */ int ec_eoedev_stop(struct net_device *dev /**< EoE net_device */) { ec_eoe_t *eoe = *((ec_eoe_t **) netdev_priv(dev)); netif_stop_queue(dev); eoe->tx_queue_active = 0; eoe->opened = 0; ec_eoe_flush(eoe); EC_INFO("%s stopped.\n", dev->name); if (!eoe->slave) EC_WARN("device %s is not coupled to any EoE slave!\n", dev->name); else { eoe->slave->requested_state = EC_SLAVE_STATE_INIT; eoe->slave->error_flag = 0; } return 0; } /*****************************************************************************/ /** Transmits data via the virtual network device. */ int ec_eoedev_tx(struct sk_buff *skb, /**< transmit socket buffer */ struct net_device *dev /**< EoE net_device */ ) { ec_eoe_t *eoe = *((ec_eoe_t **) netdev_priv(dev)); ec_eoe_frame_t *frame; #if 0 if (skb->len > eoe->slave->sii_tx_mailbox_size - 10) { EC_WARN("EoE TX frame (%i octets) exceeds MTU. dropping.\n", skb->len); dev_kfree_skb(skb); eoe->stats.tx_dropped++; return 0; } #endif if (!(frame = (ec_eoe_frame_t *) kmalloc(sizeof(ec_eoe_frame_t), GFP_ATOMIC))) { if (printk_ratelimit()) EC_WARN("EoE TX: low on mem. frame dropped.\n"); return 1; } frame->skb = skb; spin_lock_bh(&eoe->tx_queue_lock); list_add_tail(&frame->queue, &eoe->tx_queue); eoe->tx_queued_frames++; if (eoe->tx_queued_frames == EC_EOE_TX_QUEUE_SIZE) { netif_stop_queue(dev); eoe->tx_queue_active = 0; } spin_unlock_bh(&eoe->tx_queue_lock); #if EOE_DEBUG_LEVEL > 0 EC_DBG("EoE TX queued frame with %i octets (%i frames queued).\n", skb->len, eoe->tx_queued_frames); if (!eoe->tx_queue_active) EC_WARN("EoE TX queue is now full.\n"); #endif return 0; } /*****************************************************************************/ /** Gets statistics about the virtual network device. */ struct net_device_stats *ec_eoedev_stats(struct net_device *dev /**< EoE net_device */) { ec_eoe_t *eoe = *((ec_eoe_t **) netdev_priv(dev)); return &eoe->stats; } /*****************************************************************************/